System for locking optical fibers within a fiber optic cable

ABSTRACT

The present disclosure includes a fiber optic cable having a conduit including a conduit wall defining a conduit passage that extends longitudinally through the conduit. The conduit also includes an adhesive injection port defined through the conduit wall and at least one optical fiber within the conduit passage. The cable further includes a fiber lock including an adhesive volume in communication with the adhesive injection port. The adhesive volume includes a main adhesive volume positioned within the conduit passage and bonded to the optical fiber. The main adhesive volume is fixed to prevent longitudinal movement relative to the conduit.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a National Stage Application of PCT/US2018/021310,filed on Mar. 7, 2018, which claims the benefit of U.S. PatentApplication Ser. No. 62/468,095, filed on Mar. 7, 2017, the disclosuresof which are incorporated herein by reference in their entireties. Tothe extent appropriate, a claim of priority is made to each of the abovedisclosed applications.

TECHNICAL FIELD

The present disclosure relates generally to fiber optic cables. Moreparticularly, the present disclosure relates to systems and methods forlocking optical fibers within fiber optic cables.

BACKGROUND

Fiber optic cables typically include a jacket containing one or moreoptical fibers. Cable jackets can have a variety of shapes such as roundcable jackets and flat cable jackets. Fiber optic cables also typicallyinclude reinforcing elements such as Aramid yarns or glass reinforcedpolymer rods that are positioned within or embedded within the cablejackets. The optical fibers within the fiber optic cables can includesingle optical fibers, loose optical fibers, and ribbonized opticalfibers. In one configuration, one or more unbuffered optical fibers arepositioned within a buffer tube within the fiber optic cable. The buffertube can include a water blocking gel that fills voids within the buffertube. In other examples, a separate buffer tube can be eliminated andthe optical fibers can be positioned within a passage defined by thejacket itself.

Under certain circumstances, tension can be applied to optical fiberswithin a fiber optic cable. This can be problematic when the tensioncauses the fibers to pull-back on ferrules of fiber optic connectorsmounted at the ends of the optical fibers. When this occurs, the fiberoptic connectors can be disconnected from mating fiber optic connectors.Tension can be applied to optical fibers by a variety of circumstancessuch as uncoiling the cable, or jacket expansion caused by temperaturevariations and/or axial loads applied to cable jackets. There is a needto efficiently and effectively anchor optical fibers within a fiberoptic cable to, among other things, prevent pull-back loads from beingapplied by the optical fibers to ferrules corresponding to fiber opticconnectors mounted at the ends of the optical fibers.

SUMMARY

Aspects of the present disclosure relate to a fiber optic cable having aconduit including a conduit wall defining a conduit passage that extendslongitudinally through the conduit. The conduit also includes anadhesive injection port defined through the conduit wall. The adhesiveinjection port extends through the conduit wall from an outer side ofthe conduit to the conduit passage. The fiber optic cable also includesat least one optical fiber within the conduit passage, and a fiber lockincluding an adhesive volume in communication with the adhesiveinjection port. The adhesive volume includes a main adhesive volumepositioned within the conduit passage and bonded to the optical fiber.The main adhesive volume is longitudinally fixed relative to theconduit.

In certain examples, the adhesive volume also includes a plug portionpositioned within the adhesive injection port. The plug portion iscontiguous with the main adhesive volume and forms a mechanicalinterlock with respect to the conduit wall. The mechanical interlockresists longitudinal movement of the optical fiber and the main adhesivevolume relative to the conduit wall.

In certain examples, the adhesive injection port defines a maximum crossdimension that is less than or equal to 50% of a maximum cross-dimensiondefined by the transverse cross-sectional shape of the cable. In certainexamples, the adhesive injection port defines an enclosed port shapehaving a maximum cross-dimension that is less than or equal to 40%, 30%or 25% of a maximum cross-dimension of the outer transversecross-sectional shape of the jacket of the fiber optic cable.

In certain examples, the adhesive injection port is formed by a punchingor drilling process.

In certain examples, the adhesive injection port is used in combinationwith vent ports to control the flow of adhesive within the fiber opticcable and to therefore locate the main adhesive volume within theconduit passage.

In certain examples, gel within the optic cable can be displaced fromthe adhesive injection port and surrounding region by introducing (e.g.,blowing) a gas such as air into the conduit passage through the adhesiveinjection port.

In certain examples, the conduit can include a cable jacket or a buffertube.

In certain examples, the use of an adhesive injection port for accessingthe conduit passage is less compromising with respect to the structureof the fiber optic cable when compared to techniques such as windowcutting, ring cutting, stripping and/or skiving.

In certain examples, the fiber lock further includes an anchor memberthat projects through the conduit wall and into the main adhesivevolume. It will be appreciated that the anchor member can extend throughthe adhesive injection port, through one of the vent ports, or through aseparate port defined through the conduit wall. In certain examples, theanchor member can include a pin, screw or other projection. In certainexamples, the anchor member can be coupled to an outer shell positionedover the cable. In certain examples, the anchor member can be unitarilyformed with the shell.

In certain examples, the fiber lock can include a deformation in theconduit wall that projects into the conduit passage and interlocks withor opposes a portion of the main adhesive volume to resist longitudinalmovement of the main adhesive volume relative to the conduit wall. Incertain examples, a plurality of deformations are defined by the conduitwall that each project into the main adhesive volume or oppose a portionof the main adhesive volume in a manner that resists axial/longitudinalmovement of the main adhesive volume relative to the conduit wall. Incertain examples, the deformations can be longitudinally offset from oneanother. In certain examples, the deformations can be longitudinallyaligned with one another and can oppose one another. In certainexamples, the deformations are caused by one or more projections from anouter shell that cause the conduit wall to be pressed inwardly into theconduit passage. In certain examples, the projections can causedeformations in a cable jacket and/or deformations in a buffer tube.

In certain examples, the deformed portion of the conduit walllaterally/radially overlaps a portion of the main adhesive volume suchthat interference or opposition between the deformation and the portionof the main adhesive body resists longitudinal movement of the mainadhesive body relative to the conduit wall.

In certain examples the deformed portion of the conduit wall forms anobstruction within the conduit passage that inhibits longitudinalmovement of the adhesive volume adhered to the one or more opticalfibers.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a connectorized fiber optic cable having a fiber lockin accordance with the principles of the present disclosure;

FIG. 2 is a cross-sectional view taken along section line 2-2 of FIG. 1;

FIG. 3 is a cross-sectional view taken along section line 3-3 of FIG. 1;

FIG. 4 is a cross-sectional view showing another fiber lock inaccordance with the principles of the present disclosure;

FIG. 5 is a cross-sectional view showing still another fiber lock inaccordance with the principles of the present disclosure;

FIG. 6 illustrates an example reinforcing configuration for providingexterior reinforcing and enhanced rigidity along a region of a fiberoptic cable having a fiber lock in accordance with the principles of thepresent disclosure;

FIG. 7 is an exploded view showing an example shell arrangement forproviding external enhanced rigidity and reinforcement of a cable alonga fiber lock in accordance with the principles of the presentdisclosure;

FIG. 8 shows the shell arrangement of FIG. 7 mounted on the fiber opticcable;

FIG. 9 shows the shell arrangement of FIG. 8 with a cover such as a heatshrink element mounted over the shell arrangement;

FIG. 10 is a top view of the shell arrangement and fiber optic cable ofFIG. 8;

FIG. 11 is a cross-sectional view taken along section line 11-11 of FIG.10, the cross-section depicts another fiber lock arrangement inaccordance with the principles of the present disclosure;

FIG. 12 is a first perspective view of an example half-shell of a shellarrangement for reinforcing a fiber lock in accordance with theprinciples of the present disclosure;

FIG. 13 is second, opposite perspective view of the half-shell of FIG.12;

FIG. 14 is a plan view showing an inside of the half-shell of FIG. 12;

FIG. 15 is a side view of the half-shell of FIG. 12;

FIG. 16 is an opposite side view of the half-shell of FIG. 12;

FIG. 17 is an end view of the half-shell of FIG. 12;

FIG. 18 is an exploded view showing two of the half-shells of FIG. 12aligned with respect to a fiber lock region in accordance with theprinciples of the present disclosure;

FIG. 19 is perspective view showing the half-shells of FIG. 18 assembledon the fiber optic cable;

FIG. 20 is a top view of the shell arrangement of FIG. 19;

FIG. 21 is a cross-sectional view taken along section line 21-21 of FIG.20;

FIG. 22 is a first perspective view of another half-shell that is partof a shell arrangement for reinforcing a fiber-lock location along afiber optic cable;

FIG. 23 is a second, opposite perspective view of the half-shell of FIG.22;

FIG. 24 is a plan view showing an inside of the half-shell of FIG. 22;

FIG. 25 is an end view of the half-shell of FIG. 22;

FIG. 26 is a side view of the half-shell of FIG. 22;

FIG. 27 is an opposite side view of the half-shell of FIG. 22;

FIG. 28 shows two of the half-shells of the FIG. 22 aligned with afiber-lock location of a fiber optic cable;

FIG. 29 shows the half-shells of FIG. 28 assembled on the fiber opticcable at the fiber-lock location;

FIG. 30 is a top view of the shell arrangement of FIG. 29;

FIG. 31 is a cross-sectional view taken along section line 31-31 of FIG.30;

FIG. 32 is a first perspective view of still another half-shell that ispart of a shell arrangement in accordance with the principles of thepresent disclosure for reinforcing a fiber-lock location along a fiberoptic cable;

FIG. 33 is a second, opposite perspective view of the half-shell of FIG.32;

FIG. 34 is a plan view showing an inside of the half-shell of FIG. 32;

FIG. 35 is a first side view of the half-shell of FIG. 32;

FIG. 36 is a second, opposite side view of the half-shell of FIG. 32;

FIG. 37 is end view of the half-shell of FIG. 32;

FIG. 38 shows two of the half-shells of FIG. 32 that form a shellarrangement for reinforcing a fiber-lock location along the length of afiber optic cable, the half-shells are shown exploded relative to thefiber-lock location;

FIG. 39 shows the half-shells of FIG. 38 mounted at the fiber-locklocation of the fiber optic cable;

FIG. 40 is cross-sectional view taken along section line 40-40 of FIG.39;

FIG. 41 is a first perspective view of the further half-shell that ispart of a shell arrangement for reinforcing a fiber-lock location alonga fiber optic cable;

FIG. 42 is a second, opposite perspective view of the half-shell of FIG.41;

FIG. 43 is a plan view showing an inside the half-shell of FIG. 41;

FIG. 44 is a first side view of the half-shell of FIG. 41;

FIG. 45 is a second, opposite side view of the half-shell of FIG. 41;

FIG. 46 is an end view of the half-shell of FIG. 41;

FIG. 47 is an exploded view showing two of the half-shells of FIG. 41forming a shell assembly aligned with a fiber lock location of a fiberoptic cable;

FIG. 48 shows the shell arrangement of FIG. 47 mounted on the fiberoptic cable;

FIG. 49 is a cross-sectional view taken along section line 49-49 of FIG.48;

FIG. 50 is a first perspective view of another example half-shell thatis part of a shell arrangement for a reinforcing a fiber-lock locationof a fiber optic cable in accordance with the principles of the presentdisclosure;

FIG. 51 is a second, opposite perspective view of the half-shell of FIG.50;

FIG. 52 is a plan view showing an inside of the half-shell of FIG. 50;

FIG. 53 is a first side view of the half-shell of FIG. 50;

FIG. 54 is a second, opposite side view of the half-shell of FIG. 50;

FIG. 55 is an end view of the half-shell of FIG. 50;

FIG. 56 is an exploded view showing two of the half-shells of FIG. 50aligned with a fiber-lock location of a fiber optic cable;

FIG. 57 shows the half-shells of FIG. 56 mounted at the fiber-locklocation of the fiber optic cable; and

FIG. 58 is a cross-sectional view taken along section line 58-58 of FIG.57.

DETAILED DESCRIPTION

FIG. 1 illustrates a connectorized fiber optic cable assembly 20 inaccordance with the principles of the present disclosure. Theconnectorized fiber optic cables assembly 20 includes a fiber opticcable 22. A portion of the fiber optic cable 22 is shown schematicallyarranged in a coil 24 which is representative of the fiber optic cable22 being wrapped around a spool. The fiber optic cable 22 is depicted asa flat cable having an elongate cross-sectional shape (see FIG. 2). Inother embodiments, the fiber optic cable could have other transversecross-sectional shapes such as a round shape, a butterfly shape, orother shapes. It will be appreciated that aspects of the presentdisclosure relate to single-fiber fiber optic cables and multi-fiberfiber optic cables. In the case of multi-fiber fiber optic cables, theoptical fibers can be arranged in a loose-tube configuration or can beribbonized.

Referring still to FIG. 1, the connectorized fiber optic cable assembly20 includes a fiber optic connector 26 mounted at one end of the fiberoptic cable 22. The fiber optic connector 26 includes a ferrule 28supporting the ends of a plurality of optical fibers 30 of the fiberoptic cable 22. The ferrule 28 is moveable in a forward axial directionrelative to a main body 32 of the fiber optic connector. A spring 34biases the ferrule 28 outwardly in an axial direction from the main body32.

It will be appreciated that the fiber optic cable 22 can be exposed tocertain conditions that cause the optical fibers 30 to move within thefiber optic cable 22. For example, unspooling of the coil 24 can attimes cause the optical fibers 30 to be pulled back within the fiberoptic cable 22 relative to the fiber optic connector 26. When thisoccurs, the optical fibers 30 can pull the ferrule 28 rearwardlyrelative to the main body 32 of the fiber optic connector 26 against thebias of the spring 34. The pulling back of the ferrule 28 can cause thefiber optic connector 26 to disconnect from a corresponding mated fiberoptic connector. Therefore, it is desirable to provide a configurationthat locks the optical fibers 30 within the fiber optic cable 22 so thatthe optical fibers 30 are prevented from moving within the fiber opticcable and pulling back on the ferrule 28.

Referring to FIGS. 1-3, the connectorized fiber optic cable assembly 20includes a fiber lock 36 for locking the optical fibers 30 at a certainlocation relative to the fiber optic cable 22. As shown at FIG. 2, thefiber optic cable 22 includes a conduit 38 including a conduit wall 40defining a conduit passage 42 that extends longitudinally through theconduit 38. The conduit 38 also includes an adhesive injection port 44defined through the conduit wall 40. The adhesive injection port 44extends through the conduit wall 40 from an outer side 46 of the conduit38 to an inner side of the conduit which defines the conduit passage 42.As depicted at FIG. 2, the conduit 38 is a buffer tube positioned withina jacket 48 of the fiber optic cable 22. In other examples, the buffertube can be eliminated and the conduit can be defined by the jacket 48.As depicted at FIG. 2, the optical fibers 30 are non-ribbonized and areloosely arranged within the conduit 38 at regions of the conduit otherthan the fiber lock. As depicted, the optical fibers 30 within theconduit 38 are coated optical fibers that typically have a diameter lessthan 260 microns. Each of the coated optical fibers can include a coresurrounded by a cladding layer and a coating layer. Example coatinglayers can include a polymeric material such as acrylate. The cable caninclude reinforcing members 31 (see FIG. 2) such as fiberglassreinforced polymer rods or metal rods. In other examples, flexibletensile reinforcing members such as aramid yarn or other string-likereinforcements can be used.

Referring still to FIG. 2, the optical fibers 30 (or at least oneoptical fiber) are positioned within the conduit passage 42 of theconduit 38. The fiber lock 36 of the fiber optic cable 22 includes anadhesive volume 52 in communication with the adhesive injection port 44.The adhesive volume 52 includes a main adhesive volume 52 positionedwithin the conduit passage 42 and bonded to the optical fibers 30. Themain adhesive volume 52 is fixed relative to the conduit 38 to preventlongitudinal movement between the conduit 38 and the main adhesivevolume 52.

The fiber lock 36 also includes an anchor for preventing longitudinalmovement between the main adhesive volume 52 and the conduit 38 and/orthe jacket 48. As depicted at FIG. 2, the anchor includes an adhesiveplug portion 54 which is part of the adhesive volume 52 and whichprojects outwardly from the main adhesive volume 52. The adhesive plugportion 54 is positioned within the adhesive injection port 44. Theadhesive plug portion 54 is contiguous with the main adhesive volume 52.The adhesive plug portion 54 forms a mechanical interlock with respectto the conduit wall 40 which resists longitudinal movement of theoptical fibers 30 and the main adhesive volume 52 relative to theconduit wall 40. Since the main adhesive volume 52 is bonded to theoptical fibers 30 and is also fixed against longitudinal movementrelative to the conduit 30, the fibers are also fixed againstlongitudinal movement relative to the conduit 38.

It will be appreciated that once the optical fibers are encased withinand bonded to the adhesive volume 50, it is undesirable to bend theadhesive volume 52 since such bending could cause breakage or otherdamage to the optical fibers 30. To prevent the main adhesive volume 52from being bent, an exterior reinforcing structure can be provided onthe fiber optic cable 22 along the length of the adhesive volume 50. Incertain examples, reinforcement and enhanced rigidity can be provided byan exterior shell arrangement 56 that mounts about the outside of thecable jacket 48. In other examples, reinforcing plates 58 (see FIG. 6)can be mounted at the fiber lock to prevent bending of the opticalfibers contained within the adhesive volume 52. The reinforcing plates56 can be secured to the fiber optic cable by a heat-shrink sleeve, aheat-shrink wrap, an over-mold, a tape-wrap, or other structures.

Referring to FIG. 3, the fiber lock 36 also includes a first vent port58 defined through the conduit wall 40 at a first location upstream fromthe adhesive injection port 44 and a second vent port 60 defined throughthe conduit wall 40 at a location downstream from the adhesive injectionport 44. In one example, the adhesive injection port 44, the first ventport 58, and the second vent port 60 are aligned along a reference line62 (see FIG. 7) that is parallel to a central longitudinal axis 64 (seeFIGS. 2 and 3) of the fiber optic cable 22. In other examples, the portscan be circumferentially offset from one another about the centrallongitudinal axis 64. In certain examples, the adhesive injection port44 defines a port axis 66 that is perpendicular relative to the centrallongitudinal axis 64 of the conduit passage 42. In other examples, theadhesive injection port 44 can extend laterally through the conduit wall40 with the port axis 66 arranged at a non-perpendicular angle relativeto the central longitudinal axis 64, or with the port axis 66 notintersecting the central longitudinal axis 64. In certain examples, alongitudinal length L of the main adhesive volume 52 is defined by andbetween the first and second vent ports 58, 60. For example, an upstreamend of the main adhesive volume 52 can correspond to the first vent port58 and a downstream end of the main adhesive volume 52 can correspond tothe second vent port 60.

In certain examples, the adhesive injection port 44, the first vent port58 and the second vent port 60 form a first set of ports 70 positionedat a first side of the conduit 38. As shown at FIG. 3, the conduit 38also defines a second set of ports 72 positioned at a second side of theconduit 38 that is opposite from the first side of the conduit 38. Thesecond set of ports 72 includes an adhesive injection port 74, a firstvent port 76 positioned upstream from the adhesive injection port 74 anda second vent port 78 positioned downstream from the adhesive injectionport 74. In certain examples, the adhesive injection port 74 of thesecond set of ports 72 is longitudinally offset from the adhesiveinjection port 44 of the first set of ports 70. Also, the first ventport 76 of the second set of ports 72 is longitudinally offset from thefirst vent port 58 of the first set of ports 70. Additionally, thesecond vent port 78 of the second set of ports 72 is longitudinallyoffset from the second vent port 60 of the first set of ports 70. Incertain examples, the vent ports function as vents when adhesive isinjected into the conduit passage 42 through either of the adhesiveinjection ports. During injection of the adhesive into the conduitpassage 42, the adhesive flows in upstream and downstream directionsfrom the adhesive injection port 44 and/or the adhesive injection port74. Adhesive flow continues in the upstream and downstream directionuntil the adhesive reaches the upstream and downstream vent ports. Atthis time, the adhesive begins to flow out of the conduit passage 42through the vent ports. Thus, the upstream and downstream vents portseffectively control the longitudinal length L of the main adhesivevolume 52 within the conduit passage 42.

In certain examples, the ports can be defined using a punching process.In other examples, techniques such as drilling or using a laser or otherenergy source to define the ports can be used. It is preferred for eachof the ports to be relatively small when compared to the overallcross-dimension of the fiber optic cable. In this way, the ports can bemore easily covered and do not provide meaningfully compromise thestructural integrity of the cable jacket or the conduit.

In certain examples each adhesive injection port has a transversecross-sectional area that is smaller than a transverse cross-sectionalarea of the conduit passage. In certain examples each adhesive injectionport has a transverse cross-sectional area that is less than one half ofa transverse cross-sectional area of the conduit passage. In certainexamples each transverse adhesive injection port has a transversecross-sectional area that is less than a third of a cross-sectional areaof the conduit passage. In certain examples each adhesive injection porthas a transverse cross-sectional area that is less than a fourth of atransverse cross-sectional area of the conduit passage. In certainexamples each adhesive injection port has a transverse cross-sectionalarea that is less than a fifth of a transverse cross-sectional area ofthe conduit passage. In certain examples each adhesive injection porthas a maximum transverse cross-dimension that is less than or equal to40%, or 30%, or 25%, or 20% of a maximum outer transversecross-dimension of the cable jacket. In certain examples, each adhesiveinjection port has a maximum cross-dimension that is less than a maximumcross-dimension of the conduit passage. In certain examples, the maximumcross-dimension of the conduit passage is at least 1.1 or 1.2 or 1.3 or1.4 times as large as the maximum cross-dimension of the adhesiveinjection port.

In certain examples, the adhesive injection port is defined by apunching or drilling process. In certain examples, the injection porthas a port shape. In certain examples, the port shape is circular orpolygonal. In certain examples, the adhesive injection port defines acentral port axis that is transversely oriented relative to alongitudinal dimension of the conduit passage and the port shape definesa port boundary that extends fully around the port axis and that iscentered about the port axis. In certain examples the central port axisis perpendicular relative to a central longitudinal axis of the conduitpassage.

To form the fiber lock, the first set of ports 70 is initially formedthrough one side of the fiber optic cable 22 and then the second set ofports 72 is defined through the opposite side of the cable 22. In thecase where the fiber optic cable includes both a jacket and buffer tube,the ports are defined through the jacket and the buffer tube. In caseswhere no buffer tube is provided inside the jacket, the ports aredefined only through the cable jacket. Once the first and second sets ofports 70, 72 have been defined, an adhesive (e.g., a thermo-set epoxy orother type of adhesive) is injected into the conduit passage 42 throughthe adhesive injection port 44. As the adhesive is injected into theconduit passage though the adhesive injection port 44, the adhesiveflows between and around the optical fibers 30 thereby encapsulating thefibers in adhesive. The adhesive flows in an upstream and downstreamdirection from the adhesive injection port 44. The injection of adhesivethrough the adhesive injection port 44 is continued until adhesivebegins to bleed from at least the first and second vent ports 58, 60.When bleeding occurs through the first and second vent ports 58, 60, itis known that the main adhesive volume 52 extends the longitudinallength L. After adhesive injection has been completed at the injectionport 44, adhesive is injected through the adhesive injection port 74. Asadhesive is injected into the conduit passage 42 through the adhesiveinjection port 74, the adhesive encapsulates the optical fibers 32 andflows in an upstream and downstream direction from the adhesiveinjection port 74. The injection of adhesive is continued until adhesivebegins to bleed from the first and second vent ports 76, 78. Thebleeding action provided by the vent ports 58, 60, 76 and 78 controlsthe distance the adhesive flows within the conduit passage 42 in theupstream and downstream directions. After the adhesive has been injectedinto the conduit passage 42, the adhesive can be cured over time orthrough a temperature-based curing process (e.g., heating over a certaintime) or other curing process (e.g., UV curing, room temperature curing,etc.). It will be appreciated that portions of the adhesive form themain adhesive volume 52 and portions of the adhesive can form adhesiveplug portions 54 positioned in the adhesive injection ports 44, 74 andin the vent ports 58, 60, 76, 78. Before or after the adhesive has beencured, a reinforcing structure such as the shell 56 or reinforcingplates 57 can be mounted over the fiber optic cable 22 along thelongitudinal length L corresponding to the extent of the main adhesivevolume 52. In this way, the exterior reinforcement prevents the mainadhesive volume 52 from being bent in a manner that may cause damage tothe optical fibers adhered within the main adhesive volume 52. Incertain examples, additional structure such as a heat-shrink wrap orsleeve can be mounted over the reinforcing structure for aestheticpurposes and/or for providing enhanced retention and sealing.

In other examples, the process steps and sequence can be modified. Forexample, in certain examples, adhesive can be injected simultaneouslythrough both of the adhesive injection ports 44, 74 until adhesivebleeds from the vent ports 58, 60, 76, 78. In other examples, the firstset of ports 70 can initially be formed and the adhesive can be injectedthrough the adhesive injection port 44 before the second set of ports 72have been formed. In this example, adhesive is injected into theadhesive injection port 44 until the adhesive bleeds from the vent ports58, 60. Next, the second set of ports 72, is defined through theopposite side of the fiber optic cable 22. Then, adhesive is injectedthrough the adhesive injection port 74 until the adhesive flows from thevent ports 76, 78. Thereafter, the adhesive is cured and the fiber lock76 location is reinforced. In cases where the cable includes a conduitthat includes gel (e.g., water blocking gel) within the conduit alongwith the optical fibers, a gas such as air can be blown into theadhesive injection port prior to injecting the adhesive. In this way,the gas can displace the gel from the volume within the conduit intendedto be occupied by the adhesive. As the gas is blown into the conduit,the gel is displaced and exits the conduit though the vent ports.

In certain examples, structure in addition to the adhesive can be usedto enhance the fixation of the optical fiber or optical fibers 30relative the conduit 38. For example, FIG. 4 illustrates an anchor 80that embeds in the main adhesive volume 52 and extends at leastpartially through the conduit wall 40. In other examples, the anchor 80extends through both the conduit wall 40 and the wall of the jacket 48.In certain examples, the anchor 80 is a projection that projects intothe main adhesive volume 52 within the conduit passage 42. In certainexamples, the anchor 80 is made of a material other than adhesive. Incertain examples, the anchor 80 is metal or plastic. In certainexamples, the anchor 80 is a projection. In certain examples, the anchor80 includes a pin. In certain examples, the anchor 80 is a separatepiece from the shell 56. In other examples, the anchor 80 is aprojection that is integrated with the shell 56 that mounts about theexterior of the fiber optic cable 22 along the length of the mainadhesive volume 52. For example, FIG. 5 shows an anchor 80A unitarilyformed with the shell 56. In the embodiment of FIGS. 4 and 5, theanchors 80, 80A are shown extending through the adhesive injection port44. In other examples, anchors can extend through the adhesive injectionport 74, the first vent port 58, the second vent port 60, the first ventport 76 or the second vent port 78. Additionally, anchors in the form ofprojections can also project through other ports defined between theadhesive injection ports and the vent ports. FIGS. 7 and 8 depict anexample reinforcing structure including two half-shells 90 that snaptogether to form a shell arrangement for enhancing the rigidity of thefiber lock 36. The half-shells 90 include latching tabs 91 and tabreceptacles 93 that provide a mechanical interlock in the form of asnap-fit connection when the half-shells 90 are mated together. FIG. 9shows a cover 95 such as shape memory sleeve mounted over the assembledhalf-shells 90. FIG. 10 is a plan view of the assembled half-shells.

FIG. 11 shows the half-shells 90 equipped with integrated anchors 80Bthat oppose each other and that extend through anchor ports 96. Theanchor ports 96 are defined through a jacket 48A of a fiber optic cable22A that does not include an interior buffer tube. Instead, the outerjacket 48A of the cable itself defines a conduit passage 42 throughwhich at least one optical fiber extends. At least one optical fiber 30Aextends through the conduit passage 42. Preferably, a plurality ofoptical fibers 30A extends through the passage 42A. In certain examples,the plurality of optical fibers 30A can be ribbonized. Similar topreviously described examples, a first set of ports 70 (e.g., adhesiveinjection port 44 and vent ports 58, 60) are defined laterally throughone side of the jacket and a second set of ports 72 (e.g., adhesiveinjection port 74 and vent ports 76, 78) are defined laterally throughan opposite side of the jacket

The anchor ports 96 are defined through the jacket 48A at locationsbetween the adhesive injection ports 44, 74 and their corresponding ventports 58, 60 and 76, 78. The anchors 80B of each opposite matinghalf-shell 90 can be configured to oppose one another. The anchors 80Bcan be pins that extend into the conduit passage 42 and that embedwithin the main adhesive volume 52. In other examples, the anchors 80Bmay be longitudinally offset from one another so as to not directlyoppose one another. The half-shells 90 are also shown including anchors80C that extend through vent ports defined through the jacket 48A. Theprojections 80C are unitary with the half-shells 90 and are constructedas pins having free ends that are embedded within the main adhesivevolume 52. In embodiments where anchors such as projections are embeddedwithin the main adhesive volume 52, it is preferred for the anchors tobe positioned within the main adhesive volume 52 before the mainadhesive volume 52 is cured. For example, the half-shells 90 can bemounted on the cable 22A prior to curing the main adhesive volume 52.

In certain examples the projections 80A-80C can be pins that aredepicted as being non-tapered. In other examples, one or more of thepins can be tapered along their lengths. As depicted, the pins havecross-dimensions that are smaller than their corresponding ports. Inother examples, the pins can have cross-dimensions that are equal to orlarger than the cross-dimensions of their corresponding ports. Incertain examples, the pins can be press-fit within their correspondingports such that the conduit wall deforms to allow the ports to expand toaccommodate the pins. It will be appreciated that the shell arrangementcan be mounted on the cable and the pins can be embedded in the adhesiveafter injection of the adhesive but before curing of the adhesive. Oncethe adhesive is cured, the pins are bonded to the adhesive and lockedwithin the adhesive.

In certain examples, shells in accordance with the principles of thepresent disclosure include two half-shells that are identical and thatare mated together. It is advantageous from a manufacturing efficiencyperspective for the half-shells to be identical to one another. However,in other embodiments, two mated shells can have different, non-identicalconfigurations. In this way, more design flexibility can be providedrelating to providing anchors at different locations. Additionally,shells having more than two pieces are also contemplated.

FIGS. 12-21 illustrate another shell arrangement 100 adapted to protectand provide rigidity to a fiber lock in accordance with the principlesof the present disclosure. In certain examples, the shell arrangement100 includes two half-shells 102 that are adapted to mate together by asnap-fit connection. In certain examples, the snap-fit connection isprovided by an arrangement including two latches 104 and two latchreceptacles 106. As shown at FIG. 18, the shell arrangement 100 can bemounted on the cable 22A of the type described above. The cable 22A canhave an elongate transverse cross-section and can include a conduitpassage 42 defined by the jacket 48A of the fiber optic cable 22A.Optical fibers 30A are depicted as being arranged in a ribbonconfiguration provided within the conduit passage 42. A fiber locklocation can include the first set of ports 70 (e.g., adhesive injectionport 44 as well as first and second vent ports 58, 60) as shown at FIG.18, and can also include the second set of ports 72 (not shown).Anchoring ports 108 can be provided between the adhesive injection portsand the vent ports. The half-shells 102 can each include at least oneanchor 110 that is preferably integrated with the half-shells 102. Forexample, the anchor 110 can be unitarily molded as a single piece witheach of the half-shells 102. In the depicted example, each of thehalf-shells 102 includes only one of the anchors 110. When the shellarrangement 100 is mounted on the fiber optic cable 22A, the anchors 110project through the anchoring ports 108 and embed with the main adhesivevolume 52 within the conduit passage 42 such that an interlock is formedbetween the anchors 110 and the main adhesive volume 52 when the mainadhesive volume 52 is cured. In certain examples, the anchors 110 arepins. When the half-shells 102 are mounted on the fiber optic cable 22A,the anchors 110 of each of the half-shells 102 are longitudinally offsetfrom one another.

FIGS. 22-31 illustrate another shell arrangement 120 in accordance withthe principles of the present disclosure. The shell arrangement 120includes two mating half-shells 122 adapted to form a protectiveenclosure over a location where optical fibers are locked in place by amain adhesive volume such as the main adhesive volume 52. The shells 122have snap-fit interlocks of the type described with respect to shells102. Each of the half-shells 122 includes a pressing projection 124 incertain examples, the pressing projections 124 can be unitarily formedwith the half-shells 122. When the half-shells 122 are mounted about afiber optic cable such as the fiber optic cable 22A, the pressingprojections 124 press into the jacket 48A of the fiber optic cable 22Athereby causing an inward deformation 126 defined by the conduit wall(e.g., the wall of the jacket 48A in the present example) that protrudesinto the conduit passage 42 and engages the main adhesive volume 52. Theinward deformation 126 is shown at FIG. 31 where the shell arrangement120 is shown mounted on the fiber optic cable 22A. It will beappreciated that the shell arrangement 120 is preferably mounted on thecable 22A prior to curing the main adhesive volume 52. In certainexamples, the inward deformations 126 can be provided at locations alongthe longitudinal length L of the main adhesive volume 52. In certainexamples, the inward deformations 126 are longitudinally offset from oneanother. In certain examples, each of the half-shells 122 includes onlyone of the pressing projections 124. In certain examples, the inwarddeformations 126 are located between the adhesive injection ports 44, 74and one of their corresponding vent ports 58, 60 and 76, 78. In certainexamples, the inward deformation 126 is embedded in the main adhesivevolume 52. In certain examples, the inward deformation forms anobstruction within the conduit passage 42 that interfaces with the mainadhesive volume to block longitudinal movement of the main adhesivevolume 50 relative to the conduit (e.g., relative to the jacket 48A inthe present example). In certain examples, the inward deformations 126interlocks with the main adhesive volume. In certain examples, theinward deformation 126 reduces a cross-dimension of the conduit passage42 by at least 5%. In certain examples, the inward deformation reduces across-dimension of the conduit passage by at least 10%.

FIGS. 32-40 illustrate still another shell arrangement 140 in accordancewith the principles of the present disclosure. The shell arrangement 140is adapted for reinforcing a longitudinal length of fiber optic cablehaving an adhesive volume therein for fixing optical fibers. The shellarrangement 140 includes two half-shells 142 that snap together to forman enclosure that clamps about a fiber optic cable. In the depictedexample, each of the half-shells 142 includes four snap-latches 144 andfour latch-receptacles 146. The interior of each of the half-shells 142includes plurality of ribs 148 adapted to embed within the jacket of thefiber optic cable when the shell arrangement 140 is snapped on the fiberoptic cable. Each of the half-shells 142 also includes twolongitudinally spaced-apart pressing projections 150. Each of thepressing projections 150 has a projection length that is longer than theprojection lengths of the individual ribs 148. In certain examples, thepressing projections 150 are projection lengths that are at least twicethe corresponding projection lengths of the ribs 148. As shown at FIG.40, when the shell arrangement 140 is snapped over the fiber optic cable22A, the pressing projections 150 press into the jacket 48A at oppositesides of the jacket 148A. This causes the material of the jacket 148 todeform inwardly thereby forming the conduit passage 42. For example, thepressing projections 140 cause the material of the jacket 48A to deforminwardly so as to define inward deformations 152 at opposite sides ofthe conduit passage 42. The pressing projections 150 of the matinghalf-shells 142 oppose one another so as to maximize deformation of theconduit passage 42. In any of the examples disclosed herein, the shellarrangements can be covered with a protective layer such as aheat-shrink tube, a lap layer or an over-mold layer.

FIGS. 41-49 illustrate still another shell arrangement 160 in accordancewith the principles of the present disclosure. The shell arrangement 160can be used to protect and provide rigidity to a fiber locking locationthat utilizes a volume of adhesive. The shell arrangement 160 includeshalf-shells 162 adapted to be mated in a snap-fit relationship about afiber optic cable. The half-shells 162 each include two snap-latches 164and two snap-receivers 166 along each opposite edge of each half-shell162. The half-shells 162 also include internal minor ribs 168 and asingle pressing projection 170. The pressing projection 170 has aprojection length longer than the projection lengths of the minor ribs168. When the half-shells 142 are snapped over a cable, the pressingprojections 170 are longitudinally offset from one another and arepositioned at opposite sides of the cable. FIG. 49 shows the shellarrangement 160 snapped over the fiber optic cable 22 at the fiber locklocation 36. The shell arrangement 160 is preferably snapped onto thefiber optic cable 22 after the adhesive volume 50 has been injected intothe conduit passage 42, but before the adhesive volume has cured. Whenthe shell arrangement 160 is snapped over the fiber optic cable 22, thepressing projections 170 press into and deform the outer jacket 48 asshown at FIG. 49. The deformation of the jacket 48 causes the buffertube forming the conduit 38 to deform inwardly. Specifically, theconduit 38 is deformed to include inward deformations 172 that projectinto the main adhesive volume 52, that mechanically interlock with themain adhesive volume 52 and that form an obstruction that resistslongitudinal movement of the main adhesive volume 52 relative to theconduit 38.

FIGS. 50-58 illustrate still another shell arrangement 180 in accordancewith the principles of the present disclosure. The shell arrangement 180includes mating half-shells 182 that are secured together by a snap-fitconnection. The snap-fit connection includes snap-latches 184 andsnap-receptacles 186 that are alternatingly provided along each edge ofeach half-shell 180. Each half-shell also includes one pressingprojection 190 adapted to form an inward deformation 192 (see FIG. 58)in the conduit passage of a fiber optic cable when the shell arrangementis mounted on the fiber optic cable. Preferably, the location of thepressing projection coincides with a location where adhesive is providedwithin the conduit passage. The pressing projection deforms the jacketof the fiber optic cable such that an inward deformation projects intothe conduit passage. The inward deformation embeds into the volume ofadhesive. The inward projection forms an obstruction within the conduitpassage. The obstruction defines a reduced passage cross-dimension ascompared to the normal cross-dimension of the conduit passage. Theobstruction prevents longitudinal movement of the main adhesive volumerelative to the conduit. Since the main adhesive volume is bonded to theoptical fibers, the optical fibers are also prevented from movinglongitudinally relative to the conduit.

As used herein, an anchor is a structure that limits or resists relativemovement between two parts or things. Also, an obstruction is astructure that blocks or forms a barrier to movement of anotherstructure. Further, a projection is a structure that projects or jutsout from another structure. Example projections include rails, pillars,plugs, ridges, posts, pins, knobs, bumps, lumps, lips, fins, arms andflanges. Moreover, a pin is an elongate body having a tip that can bepointed, rounded or flat.

What is claimed is:
 1. A fiber optic cable comprising: a conduitincluding a conduit wall defining a conduit passage that extendslongitudinally through the conduit, the conduit also including anadhesive injection port defined through the conduit wall, the adhesiveinjection port extending through the conduit wall from an outer side ofthe conduit to the conduit passage; at least one optical fiber withinthe conduit passage; a fiber lock including an adhesive volume incommunication with the adhesive injection port, the adhesive volumeincluding a main adhesive volume positioned within the conduit passageand bonded to the optical fiber, the main adhesive volume being fixed toprevent longitudinal movement relative to the conduit; and a first ventport defined through the conduit wall at a first location upstream fromthe adhesive injection port and a second vent port defined though theconduit wall at a second location downstream from the adhesive injectionport; wherein the adhesive injection port, the first vent port, and thesecond vent port are a first set of ports positioned at a first side ofthe conduit, wherein the fiber optic cable also includes a second set ofports at a second side of the conduit, the second set of ports includingan adhesive injection port, a first vent port positioned upstream fromthe adhesive injection port, and a second vent port positioneddownstream from the adhesive injection port.
 2. The fiber optic cable ofclaim 1, wherein the fiber lock also includes an adhesive plug portionwhich is part of the adhesive volume and projects outwardly from themain adhesive volume, the adhesive plug portion being positioned withinthe adhesive injection port of the first set of ports, the adhesive plugportion being contiguous with the main adhesive volume, wherein theadhesive plug portion forms a mechanical interlock with respect to theconduit wall which resists longitudinal movement of the optical fiberand the main adhesive volume relative to the conduit wall.
 3. The fiberoptic cable of claim 1, wherein the adhesive injection ports, the firstvent ports, and the second vent ports are aligned along a reference lineparallel to a central longitudinal axis of the conduit passage.
 4. Thefiber optic cable of claim 1, wherein the adhesive injection portsdefine port axes that are perpendicular relative to a centrallongitudinal axis of the conduit passage.
 5. The fiber optic cable ofclaim 1, wherein a longitudinal length of the main adhesive volume isdefined by and between the first and second vent ports.
 6. The fiberoptic cable of claim 1, wherein an upstream end of the main adhesivevolume corresponds to the first vent ports and a downstream end of themain adhesive volume corresponds to the second vent ports.
 7. The fiberoptic cable of claim 1, wherein the adhesive injection port of the firstset of ports is longitudinally offset from the adhesive injection portof the second set of ports, wherein the first vent port of the first setof ports is longitudinally offset from the first vent port of the secondset of ports, and wherein the second vent port of the first set of portsis longitudinally offset from the second vent port of the second set ofports.
 8. The fiber optic cable of claim 1, wherein the conduit includesa cable jacket or a buffer tube.
 9. The fiber optic cable of claim 1,wherein the adhesive injection ports are punched openings.
 10. The fiberoptic cable of claim 1, wherein the adhesive injection ports projectinto the conduit passage.
 11. The fiber optic cable of claim 1, furthercomprising an anchor that embeds in the main adhesive volume and extendsat least partially through the conduit wall.
 12. The fiber optic cableof claim 11, wherein the anchor is a different material than theadhesive volume.
 13. The fiber optic cable of 12, wherein the anchor ismetal or plastic.
 14. The fiber optic cable of claim 11, wherein theanchor is a projection integrated with a shell that mounts about anexterior of the fiber optic cable along the main adhesive volume. 15.The fiber optic cable of claim 14, wherein the projection is unitarilyformed with the shell.
 16. The fiber optic cable of claim 11, whereinthe anchor extends through the adhesive injection port of the first setof ports.
 17. The fiber optic cable of claim 11, wherein the anchorextends through one of the first and second vent ports of the first setof ports defined through the conduit wall.
 18. The fiber optic cable ofclaim 11, wherein the anchor is a pin.
 19. The fiber optic cable ofclaim 1, wherein the fiber lock includes an inward deformation definedby the conduit wall that protrudes into the conduit passage and engagesthe main adhesive volume.
 20. The fiber optic cable of claim 19, whereinthe inward deformation is embedded in the main adhesive volume.
 21. Thefiber optic cable of claim 19, wherein the inward deformation forms anobstruction within the conduit passage that interfaces with the mainadhesive volume to block longitudinal movement of the main adhesivevolume relative to the conduit.
 22. The fiber optic cable of claim 19,wherein the inward deformation interlocks with the main adhesive volume.23. The fiber optic cable of claim 19, wherein the inward deformationreduces a cross-dimension of the conduit passage by at least 5 percent.24. The fiber optic cable of claim 19, wherein the inward deformationreduces a cross-dimension of the conduit passage by at least 10 percent.25. The fiber optic cable of claim 19, further comprising a pressingprojection that generates an inward pressing force for causing theinward deformation to be formed by the conduit wall.
 26. The fiber opticcable of claim 25, wherein the conduit includes a buffer tube, whereinthe fiber optic cable includes a jacket surrounding the buffer tube,wherein the inward deformation is defined by the buffer tube, andwherein the pressing projection presses against an outer surface of thejacket causing the jacket to deform inwardly which in turn causes thebuffer tube to deform inwardly thereby forming the inward deformationthat protrudes into the conduit passage defined by the buffer tube. 27.The fiber optic cable of claim 26, wherein the pressing projection isintegrated with a shell that mounts about an exterior of the fiber opticcable along the main adhesive volume.
 28. The fiber optic cable of claim27, wherein the pressing projection is unitarily formed with the shell.29. The fiber optic cable of claim 27, wherein the shell includes atleast two of the pressing projections.
 30. The fiber optic cable ofclaim 29, wherein the shell includes first and second opposite pieces,and wherein each of the pieces includes at least one of the pressingprojections.
 31. The fiber optic cable of claim 30, wherein the pressingprojections are longitudinally offset from one another.
 32. The fiberoptic cable of claim 30, wherein the pressing projections are alignedand oppose one another.
 33. The fiber optic cable of claim 25, whereinthe fiber optic cable includes a jacket defining the conduit passage,and wherein the pressing projection presses against an outer surface ofthe jacket causing the jacket to deform inwardly thereby forming theinward deformation into the conduit passage.
 34. A fiber optic cablecomprising: a conduit including a conduit wall defining a conduitpassage that extends longitudinally through the conduit, the conduitalso including an adhesive injection port defined through the conduitwall, the adhesive injection port extending through the conduit wallfrom an outer side of the conduit to the conduit passage; at least oneoptical fiber within the conduit passage; and a fiber lock including anadhesive volume in communication with the adhesive injection port, theadhesive volume including a main adhesive volume positioned within theconduit passage and bonded to the optical fiber, the main adhesivevolume being fixed to prevent longitudinal movement relative to theconduit; wherein the fiber lock includes an inward deformation definedby the conduit wall that protrudes into the conduit passage and engagesthe main adhesive volume.